Geometry Pdf 166492 | Finite Geometries Anon

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Modern Developments in Geometry
Finite Geometries
Focus
Traditional Euclidean Geometry has an infinitude of points,
lines, and planes as well as a sizable collection of
theorems that continues to grow. A "miniature" geometry that
has a small number of axioms, few theorems, and most
importantly a finite number of elements is known as a finite
geometry.
We shall look at such geometries. They provide a rich
opportunity from which to study geometric structure, as well
as serve as an excellent springboard into discussion of
other geometries, such as transformational, and projective
geometry.
Discussion
Axiomatics
As stated in the Introduction, the general structure of an
axiomatic system includes:
‰ undefined terms
‰ definitions
‰ axioms or postulates
‰ theorems
‰ logic
Undefined terms refer to objects and concepts that are basic
to the discussion. They are left undefined to avoid the
creation of circular definitions. Undefined terms include:
point, line, plane, prime (space), on, and through.
Definitions provide the technical language for dealing with
objects, numbers, concepts, and relationships.
An axiom is a self-evident truth. It is not proven.
Theorems are provable statements. The proof of such
statements rely on definitions, axioms, and logic. Proofs
can also be based on previously proven theorems.
Axiomatic systems are described using the terms consistent,
independent, and complete.
Definition: An axiomatic system is said to be consistent
if neither the axioms or theorems contradict one another.
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Modern Developments in Geometry
Definition: An axiom is described as independent of other
axioms if it cannot be derived from them.
Definition: An axiomatic system is complete, if for all
correctly posed statements can be proven or disproven.
Another way of describing completeness, if it is
impossible to add a new independent axiom to the system.
FOUR-POINT GEOMETRY
Axioms
‰ There exists exactly four points.
‰ Any two distinct points are on exactly one line.
‰ Each line is on exactly two points.
Consistency for an axiomatic system can be established by
creating a model and verifying each axiom.
B
D
C
A
TœÖEßFßGßH×
PœÖÖEßF×ßÖEß G×ßÖEß H×ßÖFß G×ß ÖFß H×ßÖGß H××
Independence is much more difficult to establish. A possible
approach is to replace an axiom with its negation and
creating a model. You must do this for each axiom.
A B
C D
Inserting the negation of the last axiom.
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Modern Developments in Geometry
Completeness for a rich and comprehensive system such as
arithmetic and geometry is impossible. Kurt Gödel proved
this in 1931.
Finite Geometries
All the finite geometries of this discussion have point and
line as undefined terms, and on as the main relation. Note
that figures in geometry are sets, thus, in a finite
geometry each figure is a "finite" set. Your perception of a
line must change.
THREE-POINT GEOMETRY
Axioms
ð There exists exactly three distinct points in the
geometry.
ð Any two distinct points are on exactly one line.
ð Not all points are on the same line.
ð Any two distinct lines are on at least one point.
B
C
A
TœÖEßFßG×
PœÖÖEßF×ß ÖEßG×ßÖFßG××
Definition: Two distinct lines with a common point on
each are said to intersect or are said to be intersecting
lines.
Conjectures and Theorems
ð What kind of drawing can be made to illustrate the
geometry?
ð How many lines are in the geometry?
ð What, if any, theorems can be proved?
ð What other objects can be used besides points and
lines to represent the geometry?
ð Are there any properties or theorems from Euclidean
geometry that apply to this geometry?
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Modern Developments in Geometry
Theorem 1 Any two distinct lines are on exactly one
point.
Proof
Let 12 and be two distinct lines. By axiom there exists
at least one point T on them. Suppose there exists point
U1 on both and 2 distinct from T. By axiom there is
exactly one line on TU and . This is a contradiction to
12 and being distinct. Thus, there can be exactly one
point on 12 and .

Theorem 2 There are exactly three lines in the geometry.
Proof
From the three given points, there are three lines when
$
ˆ‰
points are taken two at a time, # œ$. Suppose there is
a fourth line. It must have a distinct point in common
with each of the other three lines. Thus, the line must
be on two of the given three points, and therefore must
be one of the other three lines (otherwise there would be
two lines on two distinct points). Therefore, there are
exactly three lines.

Theorem 3 Each line contains only two points.
FOUR-LINE GEOMETRY
Axioms
‰ There exists exactly four lines.
‰ Any two distinct lines intersect in one point.
‰ Each point is on exactly two lines.
B A
C D
E
F
TœÖEßFßGßHßIÞJ×
PœÖÖEßHßG×ßÖEßIßJ×ßÖFßHßI×ßÖFßGßJ××
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...Modern developments in geometry finite geometries focus traditional euclidean has an infinitude of points lines and planes as well a sizable collection theorems that continues to grow miniature small number axioms few most importantly elements is known we shall look at such they provide rich opportunity from which study geometric structure serve excellent springboard into discussion other transformational projective axiomatics stated the introduction general axiomatic system includes undefined terms definitions or postulates logic refer objects concepts are basic left avoid creation circular include point line plane prime space on through technical language for dealing with numbers relationships axiom self evident truth it not proven provable statements proof rely proofs can also be based previously systems described using consistent independent complete definition said if neither contradict one another cannot derived them all correctly posed disproven way describing completeness impos...

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